DE102007014005A1 - Vehicle`s cornering control device, has drive moment control unit adjusting moment between left and right wheels largely than acceleration of vehicle based on condition, value, which indicates height of acceleration or delay, and speed - Google Patents

Abstract

The device has a cornering condition-detection device determining cornering condition of a vehicle, and a vehicle speed-determination device determining speed of the vehicle. An acceleration-delay value-determination device (42) determines an acceleration/delay value, which indicates height of acceleration or delay of the vehicle. A drive moment control unit (31) adjusts a drive moment between a left wheel (14L) and a right wheel (14R) largely than the acceleration of the vehicle based on the condition, value, which indicates the height of acceleration or delay, and the speed.

Description

BACKGROUND THE INVENTION

1st area the invention

The The invention relates to a cornering control device for a vehicle.

2. Description of the prior art

Around To improve the safety of vehicles, techniques are developed which achieves vehicle stability during cornering maneuvers becomes.

For example is in the Japanese Patent Publication 3116686 the determination of the emergence of a screwing (fast Turning a vehicle) in response to the release of the accelerator pedal described according to the angle and speed of the accelerator pedal, besides the extent of Turning determined according to a base lateral acceleration value which is based on an angle of the steering wheel and the speed of the vehicle is calculated.

The Japanese Patent Publication 3116686 also discloses a technique in which the vehicle is controlled so that the occurrence a Eindrehens is prevented and the vehicle stability at a Cornering is improved.

It is, however, already when the angle and the speed of the Accelerators are easily changed, difficult to prevent the screwing in with the The technique of Japanese Patent Publication 3116686 to perform precise because is selectively determined whether a screwing occurs or not.

With In other words, it's for the driver of the vehicle difficult to foresee the movement of the vehicle, because the control to prevent screwing either on or is off, even if the accelerator pedal is not moved significantly. Therefore It is difficult to drive the vehicle stable.

SUMMARY THE INVENTION

The The present invention has been made taking this situation into consideration developed, and it is therefore an object of the invention, a cornering control device for a Vehicle to create both the cornering ability as can also improve the usability of the vehicle.

These Task is a cornering control device with the features of claim 1. Advantageous developments are the subject of claims 2 to 8th.

The Curve control device according to the invention for a Vehicle includes a drive torque control device for adjusting the drive torque between a left wheel and a right wheel, cornering state detecting means for detecting the turning state of the vehicle, a vehicle speed detecting means for detecting the speed of the vehicle, a Grundantriebsmomentdifferenzwert-setting device for Setting a basic drive torque difference value, which is the difference the drive torque between the left wheel and the right wheel indicates an acceleration / deceleration value determining means for determining an acceleration / deceleration value, which is the magnitude of the acceleration or delay indicates the vehicle, and a Grundantriebsmomentdifferenzwert-adjustment for setting the basic drive torque difference value as the desired drive torque difference according to the acceleration / deceleration value generated by the Acceleration delay value determiner was determined, and the speed of the vehicle passing through the vehicle speed detecting means has been detected. The drive torque control unit sets the drive torque between the left wheel and the right one Wheel according to the target drive torque, which by the Grundantriebsmomentdifferenzwert-adjusting device was set.

According to the present invention, the cornering ability and the operability of the vehicle can be determined by a drive torque setting between a left wheel and a right wheel based on the cornering state of the vehicle and an acceleration / deceleration value indicative of the degree of acceleration or deceleration of the vehicle , and the speed of the drive to improve things.

It is also possible, the stability to improve and maintain the acceleration capability, because in each case the drive torque of the left and right wheels greater than be set at an acceleration of the vehicle.

Besides that is it is possible effectively an occurrence of understeer by a setting the driving torque of the left wheel and the right wheel depending on increases the acceleration caused by the acceleration / deceleration value be specified to prevent.

Besides that is it is possible effectively an occurrence of oversteer (Screwing in) due to an adjustment of the drive torque of left wheel and right wheel to prevent turning of the vehicle due to increases the delay to prevent, by the acceleration / deceleration value be specified.

If the vehicle is traveling and decelerating at a relatively high speed it for the driver due to the slight occurrence of excessive screwing difficult to control the vehicle. It is according to the invention even in such cases possible, the occurrence of excessive screwing by raising the extent the setting of the drive torque of the left wheel and the right one Rades concerning the Avoid vehicle speed.

It is possible, too, give a higher priority to improving vehicle stability, so that the vehicle drives straight, in that the drive torque transmitted to the left wheel and the right wheel depends on increases reduces the speed at an acceleration of the vehicle becomes.

Besides that is it is possible the driving torque of the left wheel and the right wheel in relation to Acceleration or deceleration, the precise one and is continuously detected to change evenly, this being due to the acceleration / deceleration value obtained based on the output torque of the engine possible with a quick reaction is.

DESCRIPTION THE DRAWINGS

embodiments The invention are explained below with reference to the drawings, wherein same reference numerals the same or similar parts in all figures describe.

1 Fig. 12 is a block diagram schematically showing the entire organization of an embodiment of the present invention.

2 Fig. 10 is a block diagram schematically showing a manner of control in the embodiment of the present invention.

3 is a basic control value characteristic used for obtaining a basic control value in the embodiment of the present invention.

4 is an acceleration / deceleration coefficient characteristic curve used for obtaining an acceleration / deceleration coefficient in the embodiment of the present invention.

5 Fig. 10 is a flowchart schematically showing the control in the embodiment of the present invention.

DESCRIPTION THE PREFERRED EMBODIMENTS

The inventive embodiment will now be with reference to the attached Drawings described.

As it is in 1 is shown is an engine 2 on a vehicle 1 appropriate. The torque output from the engine 2 is about a gearbox 3 and an intermediate gear mechanism 4 on a central differential 5 transfer. The central differential 5 has a front / rear wheel limiting mechanism 19 which will be described below.

The output torque from the central differential 5 is customized to a right front wheel 8L and a left front wheel 8L via a front axle differential 6 and a respective wave 7L and 7R transfer. The output torque from the differential 5 is also customizable on a right rear wheel 14R and a left rear wheel 14L via a front hypoid gear mechanism 9 , a cardan shaft 10 , a rear hypoid gear mechanism 11 , a rear axle differential 12 and a respective wave 13R respectively. 13L transfer. The rear axle differential 12 has a right / left wheel limiting mechanism 15 which will be described below.

The front axle differential 6 , a so-called torque-detecting differential, the speed difference between the right and left wheel 8R respectively. 8L the torque input from the motor 2 mechanically limit accordingly.

The central differential 5 has differential gears 5A and 5B and with the balancing wheels 5A respectively. 5B engaged side gears 5C and 5D on. The torque input from the differential gears 5A and 5B gets on the rear wheels 14 transfer. In addition, the central differential allows 5 a turning of the front wheels 8th at a speed different from that of the rear wheels 14 which ensures that the vehicle can make a turn.

The central differential 5 also has a front / rear wheel limiting mechanism 19, which is the height of the limitation of the speed differences between the front wheels 8th and the rear wheels 14 can vary and the output torque from the engine 2 variable on each of the front wheels 8th and the rear wheels 14 can distribute.

The front / rear wheel limiting mechanism 19 is a hydraulic multi-plate clutch, the extent of limiting the speed differences between the front wheels 8th and the rear wheels 14 may vary depending on a varied oil pressure input from an engine oil pressure unit (not shown). Therefore, the distributed torque becomes variable to each of the front wheels 8th and rear wheels 14 issued.

The oil pressure output from the drive oil pressure unit to the front / rear wheel limiting mechanism 19 passing through a central differential control unit 32 is controlled, will be described below.

As mentioned above, it is based on the front / rear wheel limiting mechanism 19 possible, the traction of the vehicle 1 by increasing the speed difference between the front wheels 8th and the rear wheels 14 It is also possible to improve the cornering ability of the vehicle 1 thereby improving that the speed differences between the front wheels 8th and the rear wheels 14 not be limited.

When next is the drive system for the rear wheels described.

Each of the rear wheels 14R and 14L is with the rear axle differential 12 connected, which has a right / left wheel limiting mechanism 15 for varying the difference of the on each of the rear wheels 14R and 14L transmitted drive torque includes ..

The rear axle differential 12 has a housing 12A on. A crown wheel 16 is around the case 12A trained, and in the housing 12A is a planetary gear mechanism 12B intended. The planetary gear mechanism 12B allows a speed difference between the rear wheels 14R and 14L ,

The planetary gear mechanism 12B allows transmission of the drive torque from the engine 2 on the ring gear 16 over the cardan shaft 10 and a balance wheel 10A on each of the rear wheels 14R and 14L is discharged, the speed difference between the right rear wheel 14R and the left rear wheel 14L is not limited.

The right / left wheel limiting mechanism 15 includes a speed change mechanism 15A and a torque transmitting mechanism 15B that can change its output torque. The right / left wheel limiting mechanism 15 is used to change the torque difference between the right wheel 14R and the left wheel 14L based on the signals from an ECU 40 (Electronic control unit), wherein the torque difference to the driving conditions of the vehicle 1 equivalent.

The speed change mechanism 15A the speed of the left rear wheel varies 14L and gives the torque to the torque transmitting mechanism 15B from.

The torque transmission mechanism 15B is a wet multi-plate clutch that allows adjustment of the output torque based on the oil pressure supplied from the drive oil pressure unit.

As mentioned above, it is possible that on each of the wheels 14R and 14L To vary distributed torque individually by using a technique that the speed of the right rear wheel 14R with the speed change mechanism 15A changed and the output torque by using the torque limiting mechanism 15B established. Therefore, the drive torque input becomes one of the wheels 14R and 14L increases or decreases by decreasing or increasing the other torque.

The planetary gear mechanism 12B , the speed change mechanism 15A and the torque transmitting mechanism 15B are already known. Therefore, a description of these techniques is omitted in this embodiment.

The oil pressure input from the driving oil pressure unit to the right / left wheel limiting mechanism 15 is provided by a rear differential control unit 31 regulated. The rear differential control unit 31 and its regulation will be described below.

In a case where the vehicle 1 For example, in the forward direction and a turn to the right, the oil pressure from the driving oil pressure unit (not shown) becomes the right / left wheel limiting mechanism, for example 15 supplied, then transferred to the right rear wheel torque 14R decreases and the speed of the right rear wheel 14R reduced. Therefore, the torque and the speed of the left rear wheel 14L elevated. It is therefore possible to generate a yaw moment of the vehicle in a clockwise direction.

The drive oil pressure unit (not shown) has the following elements not shown: a reservoir, a motor pump for compressing the oil in the reservoir, a pressure sensor for detecting the oil pressure resulting from compression by the motor pump. The driving oil pressure unit further includes a solenoid-controlled valve for adjusting the oil pressure in the reservoir generated by the engine pump and a pressure-direction valve for selectively supplying the oil pressure from an oil chamber (not shown) in the right-left wheel limiting mechanism 15 or another oil chamber (not shown) in the front / rear wheel limiting mechanism 19 ,

The rear differential control unit 31 is an electric control unit having an interface, memory and a CPU, which are not shown. The rear differential control unit 31 is used to set an individual drive torque on the rear wheels 14R and 14L by the oil pressure unit, wherein the control unit 31 sends a torque distribution signal to the drive oil pressure unit, the height of the oil pressure, the difference of the drive torque between the rear wheels 14R and 14L corresponds, and the determination of the oil pressure indicates. Then the controller activates 31 the oil pressure unit for controlling the oil pressure supply to the right / left wheel limiting mechanism 15 ,

The center differential control device is an electronic control unit having an interface, memory and a CPU, which are not shown. The center differential control apparatus transmits a front / rear wheel difference limit signal, which is a signal, that is a target speed difference between the front wheels 8th and the rear wheels 14 corresponds to the driving oil pressure unit, so that the central differential control unit, the amount of limitation of the speed differences between the front wheels 8th and the rear wheels 14 regulates. The driving oil pressure unit varies the oil pressure input from the front / rear wheel limiting mechanism 19 at the central differential 5 ,

Each of the wheels 8R . 8L . 14R and 14L is with brakes 21R . 21L . 22R and 22L Mistake. The brake 21R . 21L . 22R and 22L are connected to a brake oil pressure unit (not shown) corresponding to the brakes 2R . 21L . 22R and 22L individually supplies oil pressure.

In addition, the vehicle 1 provided with a brake control device (not shown). The brake controller is an electronic control unit having an interface, memories and a CPU, which are not shown.

The brake controller transmits a brake pressure signal that is a signal corresponding to a desired brake oil pressure corresponds to the individual brakes 21R . 21L . 22R and 22L is to be increased or decreased, to the brake oil pressure unit, so that the brake oil pressure unit the oil pressure input to each of the brakes 21R . 21L . 22R and 22L varied.

The brake oil pressure unit includes a motor pump and solenoid-controlled valves for a brake oil pressure system, and the unit guides the oil pressure to the individual brakes 21R . 21L . 22R and 22L in response to commands from the brake control unit too.

As described above, the rear differential control unit (drive torque control apparatus) 31 , the center differential control unit and the brake control unit by the ECU, respectively 40 controlled.

The ECU 40 is an electronic control unit that includes an interface, memory, and a CPU that are not shown. The ECU 40 the results of the detection by wheel speed sensors, a steering angle sensor (cornering state detection means), a G sensor, a yaw rate sensor, and a vehicle speed sensor (vehicle speed detecting means) are input, the sensors not shown.

The ECU 40 comprises program files stored in the memory (not shown) which are used as basic drive torque difference value calculator (drive torque value difference value setting device) 41 , as acceleration / deceleration coefficient calculator (acceleration / deceleration value determining means) 42 and as a control value adjuster (basic drive torque difference value setting device) 43 serve. In addition, in the memory are a basic control value characteristic 44 and an acceleration / deceleration coefficient characteristic 45 saved. The basic control value characteristic 44 is determined by the basic drive torque difference value calculator 41 used. The acceleration / deceleration coefficient characteristic 45 is determined by the acceleration / deceleration coefficient calculator 42 used.

The basic drive torque difference value calculator 41 calculates a basic value representing a difference of the drive torque (basic torque difference) from the motor 2 between the left wheel 14L and the right wheel 14R on the basis of the steering angle detected by the steering angle sensor δ _SW and the vehicle speed detected by the vehicle speed sensor v _B indicates.

As indicated by the arrow A11 in 2 is shown, calculates the Grundantriebsmoment-Differenzwertrechner 41 a base-side acceleration G _Y on the basis of the steering angle δ _SW and the vehicle speed v _B. The base-side acceleration G _Y is obtained by the following formula (1):

In the formula (1), "A" stands for a stability factor of the vehicle 1 , and "L" stands for the wheelbase of the vehicle 1 ,

Then the basic drive torque difference calculator receives 41 by application of the basic lateral acceleration G _Y on the principle value characteristic 44 a basic _{control value} T _AYCO , the basic _instruction to the rear _{differential control unit} 31 means (see arrow A12 in 2 ).

On the basic control value characteristic 44 The base-side acceleration G _{Y forms} the horizontal axis, and the basic _{control value} T _AYCO forms the vertical axis. On the basic control value characteristic 44 For example, the relationship is defined such that the absolute value of the basic control value T _{AYCO is increased} relative to the increases of the absolute value of the basic _{lateral acceleration} G _Y. When the base-side acceleration G _{Y is} positive (G _Y > 0), the vehicle is running 1 to the left. When the base-side acceleration G _{Y is} negative (G _Y <0), the vehicle is running 1 to the right.

The basic control value characteristic 44 is usually set so that the yaw moment of the vehicle 1 the increases of the absolute value of the base-side acceleration G _Y by In struction of the rear differential control unit 31 is increased. The basic _{control value} T _AYCO is set by the _{control value adjuster} 43 set. This will be described below.

The acceleration / deceleration coefficient calculator 42 calculates an acceleration / deceleration coefficient (acceleration / deceleration value) K _{AD of} the vehicle 1 in the following way.

As indicated by the arrow A13 in FIG 2 is shown, the acceleration / deceleration coefficient calculator determines 42 first, the output torque T _E from the engine 2 on the basis of an angle θ _ACC of the accelerator pedal detected by the accelerator pedal position sensor and the rotational speeds N _{E of} the engine 2 caused by the crank angle of the engine 2 obtained by a crank angle sensor.

As indicated by the arrow A14 in 2 is shown, the acceleration / deceleration coefficient calculator determines 42 next, an end reduction ratio R _{T of} the transmission 3 on the basis of the engine speeds N _E and an average speed v _{W of} the wheels 8L . 8R . 14L and 14R that is detected by the wheel speed sensors.

Then get the acceleration / deceleration coefficient calculator 42 a momentary drive torque T _DR (see arrow A15 in FIG 2 ) by multiplying the output torque T _E and the final reduction ratio R _T. Finally, get the acceleration / deceleration coefficient calculator 42 the acceleration / deceleration coefficient K _AD (see arrow A16 in FIG 2 by applying the instantaneous drive torque T _DR and the vehicle speed v _B to the acceleration / deceleration coefficient characteristic 45 ,

As it is in 4 is the acceleration / deceleration coefficient characteristic 45 a three-dimensional characteristic defining the relationship between the current drive torque T _DR and the acceleration / deceleration coefficient K _AD based on the vehicle speed v _B. On the characteristic 45 For example, lines v _B1 , v _B2 and v _{B3 are} shown as an example. The line v _B1 applies to the case that the vehicle speed v _{B is} comparatively low, the line v _B2 in the case where the vehicle speed is in the middle range, and the line v _B3 in the case where the vehicle speed v _{B is} relatively high is.

On the acceleration / deceleration coefficient characteristic 45 means an area in which the instantaneous drive torque T _{DR is} positive (T _DR > 0) that the vehicle 1 is accelerated, and another region in which the actual driving torque T _DR is negative (T _DR <0) means that the vehicle 1 is delayed.

The line v _B1 , which shows the case that the vehicle speed v _{B is} relatively low, is defined to increase in proportion to increases in the instantaneous drive torque T _DR with the gradient θ ₁ when the vehicle 1 is accelerated (ie within the range in which the instantaneous drive torque T _{DR is} positive (T _DR > 0)). If the vehicle 1 whereas, on the other hand, within the range in which the instantaneous drive torque T _{DR is} negative (T _DR <0)), the line v _B1 is defined to be in relation to decreases in the instantaneous drive torque T _DR with the slope θ ₂ falls.

The relationship between the slope θ ₁ and the slope θ ₂ is represented by the following formula (2). | θ 1 | <| θ 2 | (2)

The line v _B2 , which applies in the case that the vehicle is traveling at a mean speed v _B , is defined to increase in proportion to the increase in the instantaneous drive torque T _DR with the slope θ ₃ within the range in which the instantaneous drive torque T _{DR is} positive.

In contrast, in the region in which the instantaneous drive torque T _{DR is} negative, the line v _B2 is defined as falling in relation to decreases in the instantaneous drive torque T _DR with the inclination θ ₄ .

The relationship between the slope θ ₃ and the slope θ ₄ is represented by the following formula (3). | θ 3 | <| θ 4 | (3)

The line v _B3 , which holds in the case where the vehicle speed v _{B is} relatively high, is defined to increase in proportion to increases in the instantaneous driving torque T _DR with the inclination θ ₅ within the range where the vehicle speed v _B increases instantaneous drive torque T _{DR is} positive. Within the range in which the actual driving torque T _DR is negative, the line v _B3 is then set up so as θ decreases in the actual driving torque T _DR in accordance with the slope falls. ₆

The relationship between the slope θ ₅ and the slope θ ₆ is represented by the following formula (4). | θ 5 | <| θ 6 | (4)

As mentioned above, when the vehicle is decelerating 1 in all lines v _B1, v and _B2 v _B3, the rate of change of acceleration / deceleration coefficient K _AD with respect to the actual driving torque T _DR greater than at an acceleration of the vehicle 1 , Although all the slopes θ ₁ to θ _{6 of} the lines v _B1 , v _B2, and v _B3 are different from each other, each acceleration / deceleration coefficient K _AD is set so as to decrease correspondingly to the limitation of the instantaneous driving torque T _DR .

In 1 receives the control value adjuster 43 a setpoint control value T _AYC , the Hinterachsdifferenzialsteuergerät 31 by the adjustment of the basic _{control value} T _AYC0 by the basic _{drive torque difference value calculator} 41 , according to which the acceleration / deceleration coefficient K _AD obtained by the acceleration / deceleration characteristic was obtained 45 was obtained.

As indicated by an arrow A17 in 2 is shown receives the Regelwerteinsteller 43 the target control value T _AXC by multiplying the basic _{control value} T _AYC0 and the acceleration / deceleration _coefficient K _AD , and then transmits the adjuster 43 the target control value T _AYC to the Hinterachsdifferenzialsteuergerät 31 ,

The target control value T _AYC gives the difference between the torque X _{R of} the right rear wheel 14R and the moment X _{L of} the left rear wheel 14L at (X _R - X _L ) [N · m]. However, the target control value T _AYC can also specify the torque variables individually (ie, the torque of the right rear wheel 14R : X _R [N · m], the torque of the left rear wheel 14L : X _L [N · m]). Alternatively, it is possible to modify the target control value T _AXC so as to indicate the torques individually as a percentage (ie, the torque of the left rear wheel 14L : Y _L [%], the torque of the right rear wheel 14R : Y _R [%]).

When the target control value T _{AYC is} positive (T _AYC > 0), the rear differential control unit controls 31 the torque difference between the left rear wheel 14L and the right rear wheel 14R such that a left or right turn of the vehicle 1 is prevented. On the other hand, if the target control value T _{AYC is} negative (T _AYC <0), the rear differential control unit controls 31 the torque difference between the left rear wheel 14L and the right rear wheel 14R so that a curve of the vehicle 1 is supported to the left or right.

Consequently, the controller adjusts 43 the drive torque more when the vehicle 1 is accelerated than when the vehicle 1 because the rate of change of the acceleration / deceleration coefficient K _{AD is} delayed on the acceleration / deceleration coefficient characteristic 45 is defined on all lines v _B1 , v _B2 and v _B3 .

If the vehicle 1 is accelerated, provides the Regelwerteinsteller 43 the drive torque of the left rear wheel 14L and the right rear wheel 14R so that a cornering of the vehicle 1 Increases in the acceleration / deceleration coefficient K _AD is supported accordingly, whereas in a deceleration of the vehicle 1 the control value adjuster 43 the drive torque of the left rear wheel 14L and the right rear wheel 14R is set to prevent cornering in accordance with a decrease in the acceleration / deceleration coefficient K _AD because the acceleration / deceleration coefficient K _{AD is} on the acceleration / deceleration coefficient characteristic 45 is set to decrease reductions in the instantaneous driving torque T _DR correspondingly on all lines (the vehicle speed) v _B1 , v _B2 and v _B3 .

Consider the speeds v _B1 , v _B2 and v _B3 individually when the vehicle 1 is delayed, the Regelwerteinsteller increases 43 for preventing the vehicle from turning 1 the amount of adjustment of the drive torque on the left rear wheel 14L and the right rear wheel 14R according to the increases of the vehicle speed v _B at each level of the current drive torque T _DR , since the acceleration / deceleration coefficient K _{AD is} on the acceleration / deceleration coefficient characteristic 45 is set so that it decreases according to the increases in the vehicle speed v _B.

If the vehicle 1 is accelerated, reduces the Regelwerteinsteller 43 the extent of adjustment of the drive torque of the left rear wheel 14L and the right rear wheel 14R in support of turning the vehicle 1 the increases of the vehicle speed v _B corresponding to each level of the instantaneous drive torque T _DR , since the acceleration / deceleration coefficient K _AD on the Be schleunigungs- / deceleration coefficient characteristic 45 is set so that it decreases according to the increases in the vehicle speed v _B.

Of the Operation and the effect of the present embodiment of the invention will be now described as follows.

In a step S11 in FIG 5 reads the basic drive torque difference value calculator 41 the result of the detection by the steering angle sensor and the vehicle speed sensor. The acceleration / deceleration coefficient calculator 42 accordingly reads each result of the detection by the vehicle speed sensor, the accelerator pedal position sensor, the crank angle sensor and the wheel speed sensors.

Then the basic drive torque difference calculator calculates 41 the base-side acceleration G _Y on the basis of the steering angle δ _SW detected by the steering angle sensor and the vehicle speed v _B detected by the vehicle speed sensor (step S12). The computer 41 then obtains _Y by applying the base-side acceleration G _Y on the basic control value characteristic 44 the basic _{control value} T _AYCO . It is possible to _obtain the basic _{control value} T _AYCO in the manner of a positive feedback by the detection of the steering angle δ _SW , which represents the intention of the driver, to what extent the vehicle 1 should drive a curve.

Then, the acceleration / deceleration coefficient calculator determines 42 the engine torque T _EG based on the accelerator pedal angle θ _ACC and the engine speed N _E (step S14). The computer 42 also determines the final reduction ratio R of the transmission _T 3 on the basis of the engine speed N _E and an average speed v _W (step S15).

In addition, the acceleration / deceleration coefficient calculator is obtained 42 the instantaneous drive torque T _DR by multiplying the determined motor torque T _EG and the end reduction ratio R _T (step S16). The computer 42 obtains the acceleration / deceleration coefficient K _AD by applying the current drive torque T _DR and the vehicle speed v _B (step S17).

Afterwards receives the Regelwerteinsteller 43 the target control value T _{AY> C} by multiplying the basic _{control value} T _{AYCO obtained} in the step S13 and the acceleration / deceleration _coefficient K _{AD obtained} in the step S17 (step S18).

Next, the control value adjuster transfers 43 the obtained target control value T _AYC to the Hinterachsdifferenzialsteuergerät 31 , The rear differential control unit 31 then helps or prevents the vehicle from turning 1 by adjusting the drive torque between the left rear wheel 14L and the right rear wheel 14R in accordance with the target control value T _AYC (step S19).

consequently can the embodiment of the invention offer the following effects and / or benefits.

It is possible the cornering ability and the operability of the vehicle 1 improve as the drive torque between the left rear wheel 14L and the right rear wheel 14R is set not only on the basis of the steering angle δ _SW , but also on the basis of the acceleration / deceleration coefficient K _AD , which is based on the acceleration or deceleration of the vehicle 1 and based on the vehicle speed v _B.

It is also possible to effectively over-tighten by individually adjusting the drive torque on the left rear wheel 14L and the right rear wheel 14R corresponding to the decreases in the acceleration / deceleration coefficient K _AD (ie, corresponding to the increases in the deceleration of the vehicle 1 ) to avoid turning the vehicle 1 to prevent. This scheme has been developed in the sense that a screwing can easily happen when the pressure on the front wheels 8L and 8R is increased and the pressure on the rear wheels 14L and 14R is reduced.

If the vehicle 1 turning and decelerating at a relatively high speed, it is difficult for the driver to control the vehicle because of the excessive occurrence of excessive turning. Even in such cases, with the embodiment of the present invention, it is possible to cause excessive screwing by increasing the amount of adjustment of the drive torque on the left rear wheel 14L and the right rear wheel 14R with respect to the vehicle speed v _B to prevent.

In addition, it is possible to effectively prevent understeer because the drive torque of the left rear wheel 14L and the right rear wheel 14R Increases in the acceleration / deceleration coefficient K _AD (ie, increases in the acceleration of the vehicle 1 accordingly) to turn the vehicle 1 to support.

This scheme was developed with a view to understeer that can easily occur because of the pressure on the front wheels 8L and 8R is reduced and the pressure on the rear wheels 14L and 14R the increases in the acceleration of the vehicle 1 is increased accordingly.

If the vehicle 1 driving and accelerating at a relatively high speed is for the driver a control of the vehicle 1 difficult if the exaggerated trying to prevent understeer, since the stability of the vehicle 1 lost. Even in such cases, it is possible with the embodiment according to the invention to give the improvement of the vehicle stability a high priority, so that the vehicle 1 driving straight ahead, since the height of the adjustment of the drive torque for the left rear wheel 14L and the right rear wheel 14R the increases in the vehicle speed v _B is reduced accordingly when the vehicle 1 is accelerated.

In addition, it is possible the drive torque of the left rear wheel 14L and the right rear wheel 14R to vary smoothly relative to the acceleration or deceleration detected accurately and seamlessly, and responding rapidly, since the acceleration / deceleration value K _AD obtained on the output torque T _EG from the engine is obtained 2 based.

As has been described above, the invention is not on the above embodiments limited, but covers all changes and modifications that are not within the scope of the invention differ.

In the above-mentioned embodiment, the front differential corresponds 6 , which is a torque-sensing differential, which mechanically determines the difference in speed between right and left wheels 8R and 8L limit, the torque output of the engine 2 , However, it may also have a different differential than the front axle differential 6 be used.

In addition, the right / left wheel limiting mechanism 15 not only on the rear axle differential 12 but also on the front axle differential 6 be used.

In the above embodiment, the vehicle is 1 a four-wheel drive vehicle, however, the invention can also be applied to a front wheel drive vehicle or a rear wheel drive vehicle.

In addition, controls in the embodiment described above, the controller 31 the right / left wheel limiting mechanism 15 for adjusting the individual drive torque output from the engine 2 to the rear wheels 14R and 14L However, the present invention is not limited to this embodiment.

For example can be a right-wheel motor and a motor with the left Wheel can be connected, and the engine torque can be adjusted individually. In this case it is possible other drive sources, such as engines and / or machines, on the Provide vehicle.

In addition, it is possible instead of the right / left wheel limiting mechanism 15 to provide a mechanism that distributes the drive torque between the right and left wheels. For example, such a mechanism may include clutch mechanisms on each of the right and left wheels to individually adjust the clutch pressure. In addition, a drive torque distribution mechanism may be provided on both the front and rear wheels.

In addition, in the above-mentioned embodiment, the acceleration / deceleration coefficient calculator determines 42 the driving torque T _EG on the basis of the angle θ _{ACC of} the accelerator pedal and the rotational speed N _{E of} the engine 2 However, the invention is not limited to this training. For example, it is possible to increase the volume of airflow into the engine 1 to use as a substitute for the angle θ _{ACC of} the accelerator pedal.

When the angle θ _{ACC of} the accelerator pedal is used for the determination of the engine torque T _EG , it is possible to realize a quick determination of the torque T _EG since the angle θ _{ACC is} instantaneous reflects the intention of the driver. If, on the other hand, the airflow into the engine 1 is used for determining the engine torque T _EG , it is possible to determine the torque T _EG precisely.

In addition, in the above-mentioned embodiment, the acceleration / deceleration coefficient calculator is obtained 42 the instantaneous torque T _DR by multiplying the engine torque T _EG and the final reduction ratio R _{T of} the transmission 3 , The computer 42 also obtains the acceleration / deceleration coefficient K _AD by applying the instantaneous driving torque T _DR and the vehicle speed v _B to the acceleration / deceleration coefficient characteristic 45 , However, the present invention is not limited to this embodiment.

For example, it is possible to obtain an acceleration value by deriving the vehicle speed v _B and then to convert the acceleration value into the instantaneous drive torque T _DR . Alternatively, it is possible to detect the acceleration value directly by an acceleration sensor (G sensor) and then to convert the acceleration value into the instantaneous drive torque T _DR .

As explained in the embodiment, when the instantaneous drive torque T _{DR is used} for accurately determining the acceleration state or deceleration state of the vehicle, it is possible to determine the torque transmitted to the wheels by the final reduction ratio R _{T of} the transmission 3 is taken into account.

When the acceleration value obtained by converting the vehicle speed v _B is used, it is possible to directly determine the state of the acceleration / deceleration in a simple way with high durability since it is not necessary to use any special hardware.

at Use of the result of detection by a G-sensor is it is possible directly with high accuracy.

Claims (8)

A cornering control apparatus for a vehicle comprising: a drive torque control apparatus ( 31 ) for adjusting the drive torque between a left wheel ( 14L ) and a right wheel ( 14R ) cornering state detecting means for detecting the turning state of the vehicle, a vehicle speed detecting means for detecting the speed of the vehicle, a basic driving torque difference value setting means ( 41 ) for setting a basic drive torque difference value, which is the difference of the drive torque between the left wheel ( 14L ) and the right wheel ( 14R ), an acceleration-delay-value determining device ( 42 ) for determining an acceleration / deceleration value indicative of the amount of acceleration or deceleration of the vehicle and a basic driving torque difference value setting device ( 43 ) for setting the basic drive torque difference value as a target drive torque difference according to the acceleration / deceleration value detected by the acceleration / deceleration value determination means (Fig. 42 ), and the speed of the vehicle detected by the vehicle speed detecting means, wherein the drive torque control apparatus (15) 31 ) the drive torque between the left wheel ( 14L ) and the right wheel ( 14R ) according to the target drive torque set by the basic drive torque difference value setting device ( 43 ) has been set. A turning control apparatus for a vehicle according to claim 1, wherein said basic driving torque difference value setting means (16) 43 ) increases the amount of adjustment of the basic drive torque difference value more when the vehicle is accelerated than when the vehicle is decelerated. A turning control apparatus for a vehicle according to claim 1, wherein said basic driving torque difference value setting means (16) 43 ) sets the basic drive torque difference value such that turning of the vehicle is appropriately assisted with increases in the acceleration indicated by the acceleration / deceleration value, and also the basic drive torque difference value setting means (FIG. 43 ) sets the basic drive torque difference value so that rotation of the vehicle is prevented from corresponding increases in the deceleration indicated by the acceleration / deceleration value. A turning control apparatus for the vehicle according to claim 3, wherein when the vehicle is decelerating the basic drive torque difference value setting device ( 43 ) the amount of adjustment of the basic drive torque difference value correspondingly increases increases in the speed detected by the vehicle detection device. A turning control apparatus for the vehicle according to claim 3, wherein, when the vehicle is being accelerated, the basic driving torque difference value setting means (FIG. 43 ) the amount of adjustment of the basic driving torque difference value correspondingly reduces increases in the speed detected by the vehicle speed detecting means. A turning control apparatus for the vehicle according to claim 1, wherein the vehicle is provided with a motor, and the acceleration-delay value determining means (10) 42 ) determines the acceleration / deceleration value based on the output torque of the engine. A turning control apparatus for the vehicle according to claim 1, wherein said basic driving torque difference value setting means (16) 43 ) sets the basic drive torque difference value such that turning of the vehicle is appropriately assisted with increases in acceleration indicated by the acceleration / deceleration value. A turning control apparatus for the vehicle according to claim 1, wherein said basic driving torque difference value setting means (16) 43 ) sets the basic drive torque difference value so that rotation of the vehicle is prevented from corresponding increases in the deceleration indicated by the acceleration / deceleration value.